Electro-optical device and driving method for the same

ABSTRACT

A grey tone display and a driving method are described. The display comprises a light influencing layer, an electrode pad located adjacent to the layer at one side of the layer in order to define a pixel in the layer, an n-channel field effect transistors connected to the electrode pad at its source terminal, a p-channel field effect transistors connected to the electrode pad at its source terminal, a first control line connected to the drain terminal of the n-channel field effect transistor, a second control line connected to the drain terminal of the p-channel field effect transistor, a third control line connected to the gate terminals of the n-channel field effect transistor and the p-channel field effect transistor, and a control circuit for supplying control signals to the first, second and third control lines. By this configuration, the voltage of the electrode pad can be arbitrarily controlled by adjusting the input level at the gate terminals.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a grey tone display and a driving method for the same and, more particularly to a display driving system utilizing complimentary thin film gate insulated field effect transistors suitable for used in liquid crystal displays.

2. Description of the Prior Art

There have been well known in the art active liquid crystal displays which are driven by thin film transistors (TFTs). The displays of this type comprise visual panels and peripheral circuits for driving the panel. The peripheral circuit is formed by attaching a single crystalline chip containing integrated circuits on a glass substrate by tab-bonding or COG (chip on glass). The visual panel comprises a plurality of pixels each being provided with a driving TFT. The TFT is usually an N-channel FET formed within an amorphous or polycrystalline semiconductor film which is electrically coupled to a respective pixel.

FIG. 1 is a diagram illustrating the equivalent circuit of an exemplary liquid crystal display. The diagram shows only a 2×2 matrix for the sake of convenience in description whereas ordinary liquid crystal displays consist of more great numbers of pixels such as those in the form of a 640×480 matrix, a 1260×960 matrix and so on. The liquid crystal display includes a liquid crystal layer 42 disposed between a pair of glass substrates 11 and 11′ as shown in FIG. 2. Numeral 54 designates a polarizing plate. The inner surface of the glass substrate 11′ is coated with a ground electrode 53. The inner surface of the other substrate 11 is provided with a plurality of conductive pads each constituting one pixel of the display. Each conductive pad are formed together with an n-channel FET 51 whose source is electrically connected with the corresponding pad. The drains of the FETs on a similar row in the matrix is connected with a control line of the row to which control signals are supplied from a row driver 47. The gates of the n-channel FETs on a similar column are connected with a control line of the column to which control signals are supplied from a column driver 46.

In the operation of the display, the column driver 46 supplies control signals of a high level to selected columns to turn on the TFTs on the column. There are, however, undesirable cases in which the on-off action of the TFTs can not sufficiently carry out so that the output voltage of the TFT (i.e. the input to the pixel) reaches only short of a predetermined high voltage level (e.g. 5V), or the output voltage does not sufficiently fall to a predetermined low voltage (e.g. 0V). This is because of the asymmetrical characteristics of the TFTs. Namely, the charging action on the liquid crystal layer takes place in a dissimilar manner as the discharging action therefrom. Furthermore, since the liquid crystal is intrinsically insulating, the liquid crystal voltage (V_(L C)) becomes floating when the TFT is turned off. The amount of electric charge accumulated on the liquid crystal which is equivalent to a capacitance, determines the V_(L C). The accumulated charge, however, will leak through a channel resistance R_(S D) which may be formed by dust or ionized impurities or through the liquid crystal itself whose resistance R_(L C) 44 may be occasionally decreased. For this reason, V_(L C) sometimes becomes at an indeterminate intermediate voltage level. In the case of the panel having two hundred thousands to 5 million pixels, a high yield can not be expected in such a situation.

Also, in the conventional driving methods, the liquid crystal material to which control voltages are applied is subjected to an average electric field in one direction during operation. The electric field tends to cause electrolysis when continuously used. Because of this, the aging of the liquid crystal material is accelerated and the life time of the display is decreased.

Furthermore, it has been difficult to realize grey tone display, without complicated structure, capable of arbitrarily displaying a variety of visual images in various shade of grey.

BRIEF SUMMARY OF THE INVENTION

It is an object of the present invention to provide a grey tone display and a driving method for the same capable of demonstrating clear visual images.

It is another object of the present invention to provide a grey tone display and a driving method for the same capable of accurate operation.

It is a further object of the present invention to provide a grey tone display and a driving method for the same capable of arbitrarily displaying a variety of visual images in various shade of grey.

Additional objects, advantages and novel features of the present invention will be set forth in the description which follows, and in part will become apparent to those skilled in the art upon examination of the following or may be learned by practice of the present invention. The object and advantages of the invention may be realized and attained by means of the instrumentalities and combinations particularly pointed out in the appended claims.

To achieve the foregoing and other object, and in accordance with the present invention, as embodied and broadly described herein, a display comprises a light influencing medium, electrode patterns defining a plurality of pixels in the medium and a control circuit for supplying control signals to the electrode patterns. The control circuit supplies the control signal to each pixel through a switching element which comprises at least one complimentary transistors connected between a low level and a high level. By the use of the complimentary transistors, the voltage level of each pixel during its operation is prevented from fluctuating.

Particularly, the complimentary transistors are coupled in series at their source terminals to the output terminal of the complimentary transistors. The input terminal of the complimentary transistors is their gate terminals coupled to each other. By this construction, when the complimentary transistors are connected between a suitable high voltage and a suitable low voltage, the output terminal of the complimentary transistors is brought to the input level at their gate terminals from which the threshold voltage is subtracted. Accordingly, the voltage applied to the light influencing voltage can be arbitrarily adjusted by regulating the input level resulting in visual images in various shade of grey. This is particularly fitted to light influencing mediums of dispersion type liquid crystals whose thresholds have certain widths.

In typical driving methods, the display of this type is driven by applying control signals in the form of pulses to conductive pads. The light influencing medium is disposed between the conductive pads and a back electrode. The back electrode is supplied with an alternate voltage in order to make zero the average voltage applied, to the light influence medium.

In typical example, the present invention is applied to liquid crystal displays. Each pixel of the display is provided with a switching element of complimentary thin film field effect transistors which forcibly pull or push the level of the liquid crystal layer to a definite high or low voltage level rather than a floating state. Of course, the present invention can be practiced with a variety of other type transistors, other than thin film transistors, such as staggered types, coplanner types, inverted staggered types, inverted coplanner types. The channel regions of the transistors may be spoiled by introduction of a suitable impurity in order to eliminate the undesirable influence of incident light by reducing the photosensitivity of the transistors. When control transistors of a driver for supplying control signals to the switching transistors are formed also on the same substrate at its peripheral position where no light is incident, they are not spoiled by the impurity. In such a case, two types of transistors are formed on the substrate, one being spoiled and the other not being spoiled and having a carrier mobility 2 to 4 times larger than that of the spoiled transistors.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in and form a part of the invention and, together with the description, serve to explain the principles of the invention.

FIG. 1 is a schematic diagram showing an equivalent circuit of a liquid crystal display.

FIG. 2 is a cross sectional schematic view showing an general configuration of a liquid crystal display.

FIG. 3 is a schematic diagram showing an equivalent circuit of a liquid crystal display in accordance with a first embodiment of the present invention.

FIGS. 4(A), 4(B) and 4(C) are plan and cross sectional views showing the liquid crystal display illustrated in FIG. 3.

FIGS. 5(A) and 5(B) are explanatory views demonstrating operation of the liquid crystal display in accordance with the first embodiment.

FIG. 6 is a schematic view showing a system suitable for manufacturing thin film field effect semiconductor transistors in accordance with the present invention.

FIG. 7(A) is a schematic view showing a planar type magnetron RF sputtering apparatus of the system illustrated in FIG. 6 suitable for use in depositing oxide and semiconductor films.

FIG. 7(B) is an explanatory view showing the arrangement of magnets provided in the apparatus as illustrated in FIG. 7(A).

FIGS. 8(A) to 8(F) are cross sectional views showing a method of manufacturing thin film field effect semiconductor transistors suitable for the first embodiment of the present invention.

FIG. 9(A) is a schematic diagram showing an equivalent circuit of a liquid crystal display in accordance with a second embodiment of the present invention.

FIG. 9(B) is a plan sectional view showing the liquid crystal display illustrated in FIG. 9(A).

FIG. 10(A) is a schematic diagram showing an equivalent circuit of a liquid crystal display in accordance with a third embodiment of the present invention.

FIG. 10(B) is a plan sectional view showing the liquid crystal display illustrated in FIG. 10(A).

FIG. 11 is a schematic diagram showing an equivalent circuit of a liquid crystal display in accordance with a fourth embodiment of the present invention.

FIG. 12 is an explanatory diagram demonstrating operation of the complimentary transistors of the liquid crystal display in accordance with the fourth embodiment.

FIG. 13 is a chlonological diagram demonstrating operation of the liquid crystal display in accordance with the fourth embodiment.

FIG. 14 is a schematic diagram showing an equivalent circuit of a liquid crystal display corresponding to FIG. 13 in accordance with the fourth embodiment of the present invention.

FIG. 15 is a schematic diagram showing an equivalent circuit of a liquid crystal display in accordance with a fifth embodiment of the present invention.

FIG. 16 is a chlonological diagram demonstrating operation of the liquid crystal display in accordance with the fifth embodiment.

FIG. 17 is a schematic diagram showing an equivalent circuit of a liquid crystal display in accordance with a sixth embodiment of the present invention.

FIG. 18 is a chlonological diagram demonstrating operation of the liquid crystal display in accordance with the sixth embodiment.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. 3 is a diagram illustrating the equivalent circuit of a liquid crystal display in accordance with a first embodiment of the present invention. The diagram shows only a 2×2 matrix for the sake of convenience in description whereas ordinary liquid crystal displays consist of more great numbers of pixels such as a 640×480 matrix, a 1260×960 matrix. The liquid crystal display includes a liquid crystal layer 42 disposed between a pair of glass substrates 11 and 11′ as shown in FIG. 2. The inner surface of the glass substrate 11′ is coated with an electrode 53. The inner surface of the other substrate 11 is provided with a plurality of conductive pads 37 b each constituting one pixel of the display as seen from FIG. 4(A). Dashed line is enclosing one pixel in the figure. Each conductive pad 37 b are formed on the substrate together with CMOS transistors consisting of an n-channel FET 51 and a p-channel FET 41 whose sources 34 b′ and 34 b are electrically connected with the corresponding pad 37 b. The drains of the n-channel FETs of the CMOSs on a similar row is connected with a V_(D D) line 48 of the row. The drains of the p-channel FETs of the CMOSs on a similar row is connected with a Vss line 49 of the row. The gates of the p-channel and n-channel FETs of the CMOSs on a similar column is connected with a V_(G G) line of the column. The Vss lines and the V_(D D) lines are connected with a row driver 47 and supplied with control signal therefrom. The V_(G G) lines 52 are connected with a column driver 46 and supplied with control signal therefrom. The column driver 46 and the row driver 47 are formed on the projected end of the glass substrate 11 as will be understood form the illustration of FIG. 2.

When a TN liquid crystal material is used, the distance of the substrates is selected to be about 10 μm and both the inner surfaces of the substrates are provided with orientation control films which are given suitable rubbing treatment. When a ferroelectric liquid crystal (FLC) material is used, the distance of the substrates is selected to be about 1.5 to 3.5 μm, e.g. 2.3 μm and only one of the inner surfaces (the surface of the ground electrode) is provided with an orientation control film given suitable rubbing treatment. The driving voltage is 120V. When a liquid crystal material of dispersion type or a polymer liquid crystal material is used, the distance of the substrates is selected to be about 1.0 to 10.0 μm, e.g. 2.3 μm and no orientation control film is necessary. The driving voltage is 110 to 115V. In this case, polarization plates are also unnecessary and therefore the amount of available light can be relatively increased in either type of transmission and reflective types. Accordingly, whereas the liquid crystal layer possesses no threshold voltage, a large contrast in displayed images is realized and undesirable cross-talk is effectively prevented by the use of complimentary TFTs which provide a definite threshold voltage.

The operation of the complimentary transistors will be explained with reference to FIGS. 5(A) and 5(B). Let the V_(D D) line and the Vss line be in +10V and −10V respectively. The n-channel transistor 51 is tuned on and the p-channel transistor 41 turned off when a positive voltage V_(G G) is applied to the gate terminals 40 and 40′ as illustrated in FIG. 5(A). This condition continues until the source voltage level reaches V_(G G)−Vth. Namely, the n-channel transistor is turned off when the effective gate voltage (the gate voltage relative to the source voltage) comes short of the threshold voltage Vth. Of course, the n-channel transistor always supplies electric charge to the source terminal in order to maintain the source voltage level at that level coping with current leakage from the source terminal. Accordingly, the source terminal, i.e. the output level of the complimentary transistors is fixed to the V_(G G)−Vth level so that the output level can be controlled by the input gate signal.

Contrary to this, the n-channel transistor 51 is tuned off and the p-channel transistor 41 turned on when a negative voltage V_(G G) is applied to the gate terminals 40 and 40′ as illustrated in FIG. 5(B). This condition continues until the source voltage level falls to V_(G G)−Vth. Namely, the p-channel transistor is turned off when the effective gate voltage (the gate voltage relative to the source voltage) comes beyond the threshold voltage −Vth. Of course, the n-channel transistor always discharges the source terminal in order to maintain the source voltage level at that level coping with current leakage from the source terminal. Accordingly, the source terminal, i.e. the output level of the complimentary transistors is fixed to the V_(G G)−Vth level so that the output level can be controlled by the input gate signal also in this case.

Referring now to FIG. 6, FIGS. 7(A) and 7(B) and FIGS. 8(A) to 8(F), a method of manufacturing gate insulated field effect transistors 41 and 51 constituting a CMOS in accordance with a first embodiment of the present invention will be explained. FIG. 6 is a schematic view showing multi-chamber sputtering system for depositing semiconductor and oxide films by magnetron RF sputtering. The system comprises a loading and unloading pre-chamber 1 provided with a gate valve 5, a subsidiary chamber 2 connected to the pre-chamber 1 through a valve 6 and first and second individual sputtering apparatuses 3 and 4 connected to the subsidiary chamber 2 respectively through valves 7 and 8. The pre-chamber 1 is provided with an evacuation system 9 comprising a rotary pump and a turbo molecular pump in series. The subsidiary chamber 2 is provided with a first evacuation system 10 a for roughing comprising a rotary pump and a turbo molecular pump in series, a second evacuation system 10 b for high vacuum evacuation comprising a cryosorption pump and a heater 10 c located in the chamber 2 in order to heat substrates to be coated. If substrates to be coated are thermally contracted in advance by heating in the subsidiary chamber 2, thermal contraction and stress caused in films during deposition thereof on the substrate is reduced so that the adhesivity of the films can be improved.

The sputtering apparatuses 3 and 4 are individual planar type magnetron RF sputtering apparatuses suitable for exclusive use in depositing oxide films and semiconductor films respectively when used in accordance with the present invention. FIGS. 7(A) and 7(B) illustrate details of the RF sputtering apparatus. The apparatus comprises a vacuum chamber 20, a first evacuation system 12-1 for roughing consisting of a turbo molecular pump 12 b and a rotary pump 12 d respectively provided with valves 12 a and 12 c, a second evacuation system 12-2 for high vacuum evacuation comprising a cryosorption pump 12 e provided with a valve 12 f, a metallic holder 13 fixed in the lower side of the chamber 20 for supporting a target 14 thereon, formed with an inner conduit 13 a through which a coolant can flow to cool the target 14 and provided with a number of magnets 13 b such as permanent magnets, an energy supply 15 consisting of an RF (e.g. 13.56 MHz) source 15 a provided with a matching box 15 b for supplying RF energy to the holder 13, a substrate holder 16 located in the upper position of the chamber 20 for supporting a substrate 11 to be coated, a heater 16 a embedded in the substrate holder 16, a shutter 17 intervening the substrate 11 and the target 14 and a gas feeding system 18. Numeral 19 designates sealing means for ensuring air-tight structure of the vacuum chamber 20. In advance of actual deposition on the substrate 11, impurities occurring in the targets are sputtered and deposited on the shutter 17 intervening the substrate 11 and the target 14, and then the shutter is removed in order to enable normal deposition on the substrate 11. The magnets 13 b are oriented to have their N poles at the upper ends and S poles at the lower ends and horizontally arranged in a circle as illustrated in FIG. 7(B) in order to confine electrons in a sputtering region between the substrate 11 and the target 14.

Referring now to FIGS. 8(A) to 8(F) together with FIG. 6 and FIGS. 7(A) and 7(B), a method of manufacturing thin film field effect transistors 41 and 51 in accordance with the first preferred embodiment of the invention will be described in details. This exemplary method is carried out with a multi-chamber apparatus suitable for mass-production. This is, however, applicable to similar processes utilizing separate chambers without substantial modification.

10 sheets of glass substrate are mounted on a cassette and placed in the loading and unloading pre-chamber 1 through the valve 5. The substrates may be made from an inexpensive glass which can endure thermal treatment at high temperatures up to 700° C., e.g. about, 600° C. such as NO glass manufactured by Nippon Electric Glass Co. Ltd., LE-30 glass manufactured by Hoya Co. or VYCOR glass manufactured by Corning Corp. After adjusting the inner conditions of the pre-chamber 1 and the subsidiary chamber 2 to each other, the cassette is transported from the pre-chamber 1 into the subsidiary chamber 2 through the valve 6. One of the glass substrates is disposed in the first magnetron RF sputtering apparatus as shown in FIG. 7(A) by means of a transportation mechanism (not shown) and coated with a SiO₂ film 32 as a blocking film to a thickness of 1000 Å to 3000 Å in a 100° C. atmosphere (0.5 Pa) at a substrate temperature of 150° C. The output power of the apparatus is 400 W to 800 W in terms of 13.56 MHz RF energy. A single crystalline silicon or a quartz block is used as a target. The deposition speed is 30 to 100 Å/min. The coated substrate is then exchanged by another of the remaining 9 substrate which is subsequently coated with a SiO₂ film in the same manner. All the substrates mounted on the cassette are coated with a SiO₂ film by repeating this procedure. During this procedure, the transportation of a substrate between the pre-chamber 1 and the subsidiary chamber 2 has to be carried out after adjusting the pressures and the inner atmospheres of the chambers 1 and 2 to each other in order to eliminate undesirable impurities.

An amorphous silicon film 33 is next deposited in the second sputtering apparatus 4 on the SiO₂ film 32 to a thickness of 500 nm to 1 μm, e.g. 2000 Å. The total density of oxygen, carbon and nitrogen in the amorphous film is preferably between 5×10²⁰ to 5×10²¹ cm⁻³ in order to eliminate undesirable influence of incident light on the channel region of the transistor by reducing photosensitivity. The photosensitivity of the channel can be alternatively reduced by introducing an spoiling impurity selectively into the channel. In this case, the total density of oxygen, carbon and nitrogen in the amorphous film does desirably not exceed 7×10²⁰ cm³, preferably not to exceed 1×10¹⁹ cm⁻³. Such low density makes it easy to recrystallize the source and the drain to be formed in the silicon film in the latter step by thermal treatment. For the formation of the silicon film 33, the 10 substrates are placed into the apparatus 4 one after another from the subsidiary chamber 2 in the same manner and treated therein for deposition of the amorphous silicon film. The transportation of each substrate between the apparatus 4 and the subsidiary chamber 2 is carried out after adjusting the pressures and the inner atmospheres of the chambers 2 and 4 in order to eliminate undesirable impurities. This procedure is generally employed when it is desired to transport the substrates between the first or second sputtering apparatus and the subsidiary chamber, even if not particularly described hereinbelow. The atmosphere in the apparatus 4 comprises a mixture consisting of hydrogen and argon so that H₂/(H₂+Ar)=0.8 (0.2 to 0.8 in general) in terms of partial pressure. The hydrogen and argon gases have desirably purities of 99.999% and 99.99% respectively and are introduced after the inside of the apparatus 4 is evacuated to a pressure not higher than 1×10⁵ Pa. The total pressure is 0.5 Pa: the output power of the apparatus is 400 W to 800 W in terms of 13.56 MHz RF energy: a single crystalline silicon desirably containing oxygen atoms at a concentration of no higher than 5×10⁸ cm³, e.g. 1×10⁸ cm³ is used as a target: and the substrate temperature is maintained at 150° C. (deposition temperature) by the heater 16 a in the same manner. In preferred embodiments, the hydrogen proportion in the mixture may be chosen between 5% and 100%; the deposition temperature between 50° C. and 500° C., e.g. 150° C.; the output power between 1 W and 10 MW in a frequency range from 500 Hz to 100 GHz which may be combined with another pulse energy source.

Alternatively, the amorphous silicon film 33 may be deposited by low pressure CVD (LPCVD) or plasma CVD. In the case of LPCVD, the deposition is carried out by introducing disilane (Si₂H₆) or trisilane (Si₃H₈) in a suitable CVD chamber. The deposition temperature is selected at a temperature 100° C. to 200° C. lower than the recrystallization temperature of the silicon, i.e. 450° C. to 550° C., for example 530° C. The deposition speed is 50 to 200 Å/min. Boron may be introduced at 1×10¹⁵ cm³ to 1×10¹⁶ cm³ into the film by using diboran as a dopant gas together with the silane in order to make even the threshold voltages of N-type and P-type TFTs. In the case of plasma CVD, the deposition is carried out by introducing monosilane (SiH₄) or disilane (Si₂H₆) at 300° C. in a suitable plasma CVD chamber. The input energy is for example high frequency electric energy at 13.56 MHz.

The oxygen density of the semiconductor film are preferably no higher than 5×10²¹ cm⁻³ because if the oxygen density is too high, thermal treatment have to be carried out at a high temperature for a long time in order to sufficiently recrystallize the semiconductor film in a latter step. The oxygen density, however, must not be too low because leak current in the off condition of the TFT increases in response to a back light which may be provided in the liquid crystal display if particular spoiling impurity is not used. For this reason, the oxygen density is selected between 4×10¹⁹ to 4×10²¹ cm⁻³. In accordance with experiments, it was confirmed by SIMS (secondary ion mass spectroscopy analysis) that hydrogen was involved at densities of 4×10²⁰ cm³ equivalent to one atom % assuming the density of silicon being 4×10²² cm⁻³. These figures of density were minimum values of the respective elements which varied along the depth direction. The reason why such minimum values were employed is that a natural oxide existed at the surface of the semiconductor film. If it is desired to spoil the channel region, oxygen may be introduced as a spoiling agent to a portion of the semiconductor film to be a channel region to a density of 5×10²⁰ to 5×10²¹ cm⁻³ after deposition of the semiconductor film. In this case, the deposition of the semiconductor film can be carried out in order that the total density of oxygen in the semiconductor film does not exceed 7×10²⁰ cm⁻³, preferably not to exceed 1×10¹⁹ cm⁻³. Such low density makes it easy to recrystallize the source and drain regions of the semiconductor film in the latter step by thermal treatment. In this case, when TFTs for peripheral circuits located not to be exposed to illumination are formed in the same time, the mobility of the TFTs can be increased, because the oxygen introduction is prevented, resulting in a high speed operation.

After all the substrates are coated with the silicon oxide and amorphous silicon semiconductor films, thermal treatment is given thereto in the subsidiary chamber 2 by means of the heater 10 c at 450° C. to 700° C., typically at 600° C. for 12 to 70 hours in a non-oxidizing atmosphere, e.g. in hydrogen. The film is recrystallized by this treatment (thermal annealing) in the form of semi-amorphous or semi-crystalline structure.

Next, the mechanism of formation of semi-amorphous or semi-crystalline semiconductor material in accordance with the present invention will be explained. When sputtering a single crystalline silicon target in a mixture of hydrogen and argon, high energy heavy argon atoms collide with the surface of the target, dislodge therefrom clusters each consisting of several tens to several hundred thousands of silicon atoms, and deposit the clusters on a substrate to be coated. These clusters pass through the mixture gas in advance of the deposition on the substrate and are coupled with hydrogen atoms at their external surfaces in order to terminate their dangling bonds. Accordingly, when deposited on the substrate, the clusters comprise internal amorphous silicon and external ordered silicon including Si—H bonds. The Si—H bonds react with other Si—H bonds and are converted to Si—Si bonds by thermal treatment at 450° C. to 700° C. in a non-oxidizing atmosphere. These coupling of adjacent silicon atoms (Si—Si) function to let adjacent clusters be attracted to each other whereas these clusters have a tendency to convert their phases to more ordered phases (partial recrystallization). As a result, the crystalline structure of these clusters is given lattice distortion and the peak of its Raman spectra (522 cm⁻¹: the peak of single crystalline silicon) is displaced to the low frequency direction. The apparent grain diameter calculated based on the half-width is 50 to 500 Å which seems to indicate microcrystals.

The energy bands of the clusters are connected through the Si—Si bonds anchoring the clusters at the interfaces therebetween. For this reason, the polycrystalline (semi-amorphous or semi-crystalline) structure of silicon in accordance with the present invention is entirely different than usual polycrystals in which grain boundaries provide barriers against carrier transportation, so that the carrier mobility can be on the order of 15 to 300 cm²/Vsec (electron mobility) and 10 to 200 cm²/Vsec (hole mobility). Namely, the semi-amorphous or semi-crystalline structure in accordance with the present invention can be considered substantially not to include undesirable grain boundaries. Of course, if the semiconductor is subjected to high temperatures of 1000° C. or higher rather than the relatively low temperatures of 450° C. to 700° C., latent oxygen atoms come to appear at the boundaries between the clusters and form barriers like the prior art technique. The carrier mobility can be improved by increasing the strength of the anchoring. For this purpose, the oxygen density in the semiconductor film is decreased to 7×10¹⁹ cm³, desirably to 1×10¹⁹ cm³.

The amorphous silicon semiconductor film 33 is patterned by means of a photomask as indicated by {circle around (1)} to leave areas 33 and 33′ which are necessary to form N-channel and P-channel transistors. After all the substrates are coated with the silicon oxide and amorphous silicon semiconductor films and patterned as described above, the substrates are placed again in the first sputtering apparatus 3. The entire structure is then coated with a silicon oxide film 35 of a thickness of 500 Å to 2000 Å, e.g. 1000 Å by sputtering in an oxide atmosphere as illustrated in FIG. 8(B). The deposition condition is same as that of the silicon oxide film 32 explained above. The characteristics at the interface between the silicon oxide film 35 and the underlying semiconductor film 33 can be improved by applying ultraviolet rays to carry out ozone oxidation. Namely, the interface states can be decreased by utilizing photo-CVD in combination with the sputtering explained in the description of deposition of the oxide film 32. Alternatively, fluorine may be introduced in this deposition in order to fix sodium ions. In this case, the atmosphere comprises a high density oxygen (95%) including NF₃ (5%) at a total pressure of 0.5 Pa: the output power of the apparatus is 400 W in terms of 13.56 MHz RF energy: a single crystalline silicon or an artificial quartz is used as a target: and the substrate temperature is maintained at 100° C. By this procedure, the silicon oxide film 35 to be a gate insulating film includes fluorine atoms which function to terminate dangling bonds of silicon atoms so that the formation of fixed charge can be prevented at the interface between the semiconductor films 33 and 33′ and the oxide film 35. On the silicon oxide film 35 is deposited by low pressure CVD a silicon semiconductor film of 0.2 μm thickness which is highly doped with phosphorus at 1×10²¹ to 5×10²¹ cm³ followed, if desired, by coating a conductive film of 0.3 μm thickness made of molybdenum, tungsten film or a multiple film consisting of it and a MoSiO₂ or WSiO₂ film. The semiconductor film coated with the conductive (multiple) film is then patterned by photolithography with a suitable mask {circle around (2)} in order to form gate electrodes 40 and 40′.

A photoresist film 27′ is formed by the use of a photomask {circle around (3)} in order to cover the semiconductor film 33′. With the gate electrode 40 and the photoresist film 27′, self-aligned impurity regions, i.e. a source and a drain region 34 a and 34 b are formed by ion implantation of boron at 1×10¹⁵ cm² to 5×10¹⁵ cm². The intermediate region 28 of the silicon semiconductor film 33 between the impurity regions 34 a and 34 b is then defined as a channel region as illustrated in FIG. 8(C). After removing the photoresist film 27′, another photoresist film 27 is formed by the use of a photomask {circle around (4)} in order to cover the semiconductor film 33. With the gate electrode 40′ and the photoresist film 27′, self-aligned impurity regions, i.e. a source and a drain region 34 b′ and 34 a′ are formed by ion implantation of phosphorus at 1×10¹⁵ cm² to 5×10¹⁵ cm². The intermediate region 28′ of the silicon semiconductor film 33 between the impurity regions 34 a′ and 34 b′ is then defined as a channel region as illustrated in FIG. 8(D). The channel lengths of the p-channel and n-channel transistor are 10 μm respectively. The channel widths of the p-channel and n-channel transistor are 20 μm respectively. The ion implantation may instead be carried out by selectively removing the silicon oxide film 35 by the use of the gate electrode 40 or 40′ as a mask followed by direct ion implantation of boron or phosphorus.

After removing photoresist 27, the channel regions are then thermally annealed at 600° C. for 10 to 50 hours in H₂ atmosphere to make active the impurities in the drain and source regions. An interlayer insulating film 37 of silicon oxide is deposited, to a thickness of 0.2 to 0.6 μm by the same sputtering method as described above over the entire surface of the structure followed by etching by means of a photomask {circle around (5)} for opening contact holes 39 through the interlayer film 37 and the oxide film 35 in order to provide accesses to the underlying source and drain regions 34 b, 34 a, 34 b′ and 34 a′. The deposition of the interlayer insulating film 37 may be carried out by LPCVD, photo-CVD, ordinal pressure CVD (TEOS-ozone). Next, an aluminum film of 0.5 to 1 μm thickness is deposited on the structure over the contact holes 39 and patterned to form source and drain electrodes 36 b, 36 a, 36 b′ and 36 a′ by means of a photomask {circle around (6)} as illustrated in FIG. 8(F). An organic resin film 39 such as a transparent polyimide film is coated over the structure to provide a planar surface and patterned by means of a photomask {circle around (7)} to provide accesses to the source electrodes 36 b and 36 b′ followed by formation of lead electrode 37 made of a transparent conductive material such as indium tin oxide (ITO) to be electrically connected with the pad 37 b. The ITO film is deposited by sputtering at room temperature to 150° C. followed by annealing in an oxidizing atmosphere (O₂) or in air at 200 to 400° C. The pad 37 b can be formed at the same time by the deposition of the lead electrode 37. Then, the formation of CMOS transistors is finished. The mobility, the threshold voltage of the p-channel TFT are 20 cm²/Vs and −5.9 V. The mobility, the threshold voltage of the n-channel TFT are 40 cm²/Vs and 5.0 V. The glass substrate thus provided with these CMOS transistors and suitable conductive patterns as illustrated is joined with a counterpart glass substrate provided with a ground electrode at its entire inner surface followed by injection of a liquid crystal material between the two substrates. One of the advantages of the above process is that the formation of these transistors (spoiled and not spoiled) can be carried out at temperatures no higher than 700° C. so that the process does not require the use of expensive substrates such as quartz substrates and therefore suitable for large scale liquid crystal displays production methods.

In the above embodiment, thermal annealing is carried out twice at the steps corresponding to FIGS. 8(A) and 8(D). The first annealing (FIG. 8(A)), however, can be omitted to shorten the process time in the light of the second annealing.

Referring to FIGS. 9(A) and 9(B), CMOS thin film field effect transistors in accordance with a second preferred embodiment of the present invention will be illustrated. In this embodiment, two couples of CMOS transistors 51-1, 41-1, 51-2 and 51-2 are connected in parallel to the conductive pad 37 b for each pixel (as enclosed by dashed line) at their source electrodes. These CMOS transistors are manufactured in the steps explained above in conjunction with the first embodiment except that the number of the transistors is doubled. The similar elements are given similar numerals as in the first embodiment. The electrode pads 37 b have to be deposited on the V_(G G) line through a suitable insulating film therebetween. The electrical operation is substantially same as that of the first embodiment. Accordingly, two identical individual switching elements are prepared corresponding to one pixel so that when the operation of one of them is fault, the ability of information display can be maintained by firing the fault element by laser rays in virtue of the remaining CMOS transistors. For this reason, the conductive transparent pads are formed in order not to cover these TFTs.

Referring to FIGS. 10(A) and 10(B), CMOS thin film field effect transistors in accordance with a third preferred embodiment of the present invention will be illustrated. Also in this embodiment, two couples of CMOS transistors 51-1, 41-1 and 51-2 and 41-2 are connected in parallel to an electrode pad 37 b for each pixel at their source electrodes. The electrode pad 37 b, however, is separated into two portions 37 b-1 and 37 b-2 each independently connected to a corresponding one of the two CMOS transistors. These CMOS transistors are manufactured in the steps explained above in conjunction with the first embodiment except for the number of the transistors. The similar elements are given similar numerals as in the first embodiment. Then, each pixel comprises two individual sub-pixels. In accordance with this embodiment, even if the operation of one of the sub-pixels is fault, the other sub-pixel can support the operation of the pixel and therefore the deterioration of grey scales is substantially decreased.

As described above, there are following advantages in accordance with the above embodiments of the present invention:

1) Visual images can be constructed in a variety of grey shade.

2) The voltage across the liquid crystal layer is stably fixed at determinate level in accordance with the output signal from the complimentary transistors rather than in an indeterminate floating condition.

3) Margins for operational fluctuation are broadened.

4) Even if some TFTs are fault, the operation thereof is followed up to same extent.

5) The increase of the number of photomasks due to the employment of complimentary transistors is only two (photomask {circle around (3)} and {circle around (4)}) as compared with conventional cases utilizing only n-channel TFTs.

6) Since semi-amorphous or semi-crystalline semiconductors are used in place of amorphous semiconductors and the carrier mobility is increased by a factor of ten or more, the size of the TFT is substantially reduced so that little decrease of the aperture ratio is necessary even when two TFTs are formed in one pixel.

FIG. 11 is a diagram illustrating the equivalent circuit of a liquid crystal display in accordance with a fourth embodiment of the present invention. The pixel configuration as shown in FIG. 4 can be applied also for this embodiment. The diagram shows only a 2×2 matrix for the sake of convenience in description whereas ordinary liquid crystal displays consist of more great numbers of pixels such as a 640×480 matrix, a 1260×960 matrix. The liquid crystal display includes a liquid crystal layer 42 disposed between a pair of glass substrates 11 and 11′ in the same manner as the first embodiment as shown in FIG. 2. The entirety of the inner surface of the glass substrate 11′ is coated with a back electrode 53. In this embodiment, however, the electrode 53 is not ground but supplied with an offset voltage in accordance with the driving mechanism of the liquid crystal display as detailedly explained infra. The inner surface of the other substrate 11 is provided with a plurality of conductive pads 37 b each constituting one pixel of the display in the same manner as the first embodiment. Each conductive pad 37 b are formed on the substrate together with CMOS transistors consisting of an N-type FET 51 and a P-type FET 41 whose sources 34 b′ and 34 b are electrically connected with the corresponding pad 37 b. The drains of the N-type FETs of the CMOSs on a similar row are connected with a V_(D D) line 48 of the row. The drains of the P-type FETs of the CMOSs on a similar row is connected with a Vss line 49 of the row. The gates of the P-type and N-type FETs of the CMOSs on a similar column is connected with a V_(G G) line of the column. The Vss lines and the V_(D D) lines are connected with a row driver 47 and supplied with control signal therefrom. The V_(G G) lines 52 are connected with a column driver 46 and supplied with control signal therefrom.

FIG. 12 illustrates operational action of each pixel in response to several control signals applied to the V_(D D) line, the V_(S S) a line, the V_(G G) line and the back electrode. When a positive voltage is applied to the V_(D D) line and a negative voltage to the V_(S S) line, the liquid crystal voltage level at the pixel (i.e. the voltage level of the pad 37 b) follows the voltage level at the V_(G G) line and the liquid crystal voltage level is forcibly at ground if the V_(D D) line and the Vss line are commonly grounded. Accordingly, the voltage applied between the liquid crystal at the pixel is calculated by subtracting the offset (bias) voltage applied to the back electrode from the liquid crystal voltage.

The representative example of the driving method in accordance with the fourth embodiment of the present invention will be explained with reference to FIGS. 13 and 14. In FIG. 14, the 2×2 matrix of FIG. 11 is expanded to a 4×4 matrix. The configurations of them, however, are substantially identical except the number of pixels. FIG. 13 illustrates the control signals applied to the V_(D D) lines, the V_(S S) lines, the V_(G G) lines and the back electrode. The V_(D D) lines are called X_(1a), X_(2a), X_(3a) and X_(4a) from the first row to the forth row in the diagram whereas the Vss lines are called X_(1b), X_(2b), X_(3b) and X_(4b) in the same manner. The signals applied to the Vss lines are exactly the inversion of the signals to the V_(D D) line and therefore the waveforms of the Vss lines are dispensed with in the illustration. The V_(G G) lines are called Y₁, Y₂, Y₃ and Y₄ from the left column to the right column. In this driving method, the control signals applied to the V_(D D) and Vss lines are addressing signals which scan from the first row to the forth row as shown in FIG. 13. Opposed pulses are applied to the V_(D D) and Vss lines connected to one addressed row for the time width of one fourth of the frame during which all the rows are sequentially scanned. The control signals applied to the V_(G G) lines are data signals which determine the visual pattern appearing on the display.

If a pixel on the i-th row and the j-th column is desired to be actuated, a positive pulse is applied to the V_(G G) line of the j-th column at the time when the i-th row is addressed by applying opposed pulses to the VDD and Vss lines on the i-th row. In FIG. 13, the pixel on the first column and the first row (given symbol AA in FIG. 14) is actuated in the first fourth of the first frame between T₁ and T₂, the second frame between T₂ and T₃ and the fifth frame between T₅ and T₆. The back electrode is biased by a negative voltage between T₁ and T₆. The V_(D D), Vss and V_(G G) signal levels and the bias voltage are for example 20V, −20V, 120V and 110V respectively in the case that the optical characteristic of the liquid crystal is changed by the threshold voltage of 20V thereacross. Accordingly, as understood from FIG. 12, such a high voltage as 30V is applied only to the selected pixel (the AA pixel in the figure) while the voltage level applied to the other pixel can not exceed 10V. In T₆ to T₈ in FIG. 13, the voltage levels at the V_(G G) lines and the back electrode are inversed so that the sign of the applied voltage on each pixel is simply inversed. Accordingly, such a low voltage as −30V is applied only to the selected pixel (the AA pixel in the figure) while the absolute voltage level applied to the other pixel can not exceed 10V. The pixel on the first column and the first row is actuated in the sixth frame between T₆ and T₇. The inversion of the signs takes place repeatedly once per several frames to several tens of frames so that the average voltage applied to the liquid crystal approaches to zero throughout the operation resulting in effective prevention of deterioration of the liquid crystal.

In accordance with this embodiment, the voltage level of control signals applied to the liquid crystal layer can be easily adjusted to the threshold level of the liquid crystal layer only by adjusting the bias voltage level applied to the back electrode. The employment of the bias voltage makes it possible to cancel out the effect of the electric field impressed on the liquid crystal by periodically changing the polarity of the bias voltage, resulting in the prevention of electrolysis of the liquid crystal material.

Referring to FIGS. 15 and 16, a liquid crystal display and a method for driving the display in accordance with a fifth preferred embodiment of the present invention will be illustrated. In this embodiment, two couples of CMOS transistors 41-1, 51-1 and 41-2′, 51-2′ are connected in parallel to an electrode pad 33 for each pixel (as enclosed by dashed line) at their source electrodes. These CMOS transistors are manufactured in the steps explained above in conjunction with the first embodiment except that the number of the transistors is doubled. The similar elements are given similar numerals as in the first embodiment. The electrical operation is substantially same as that of the third embodiment. Accordingly, two identical individual switching elements are prepared corresponding to one pixel so that when the operation of one of them is fault, the ability of information display can be maintained by firing the fault element by laser rays in virtue of the remaining CMOS transistors. For this reason, the conductive transparent pads are formed in order not to cover these TFTs.

The representative example of the driving method in accordance with the third embodiment of the present invention will be explained with reference to FIG. 16. In FIG. 16, explanation is made for the display as shown in FIG. 15 but expanded in a 4×4 matrix. The configuration, however, is substantially identical except the number of pixels. FIG. 16 illustrates the control signals applied to the V_(D D) lines, the V_(S S) lines, the V_(G G) lines and the back electrode in the same manner as the second embodiment. In this driving method, the control signals applied to the V_(G G) lines are addressing signals which repeatedly scan from the first row to the fourth row as shown in FIG. 16. A negative or positive pulse is applied to the V_(G G) line connected to an addressed column. The control opposite signals applied to the V_(D D) and Vss lines are data signals which determine the visual pattern appearing on the display.

If a pixel on the i-th row and the j-th column is desired to be actuated, opposed pulses are applied to the V_(D D) and Vss lines of the i-th row at the time when the j-th column is addressed by applying a positive pulse to the V_(G G) line on the j-th column. In FIG. 16, the pixel on the first column and the first row is actuated in the first frame between T₁ and T₂, the second frame between T₂ and T₃ and the fifth frame between T₅ and T₆. The back electrode is biased by a negative voltage between T₁ and T₆. The V_(D D), Vss and V_(G G) signal levels and the bias voltage are for example 20V, −20V, 120V and 110V respectively in the case that the optical characteristic of the liquid crystal is changed by the threshold voltage of 20V. Accordingly, as understood from FIG. 12, such a high voltage as 30V is applied only to the selected pixel while the voltage level applied to the other pixel can not exceed 10V. In T₆ to T₈ in FIG. 16, the voltage levels at the V_(G G) lines and the back electrode are inversed so that the sign of the applied voltage on each pixel is simply inversed. Accordingly, such a low voltage as −30V is applied only to the selected pixel while the absolute voltage level applied to the other pixel can not exceed 10V. The pixel on the first column and the first row is actuated in the sixth frame between T₆ and T₇. The inversion of the signs takes place repeatedly once per several frames to several tens of frames so that the average voltage applied to the liquid crystal approaches to zero resulting in effective prevention of deterioration of the liquid crystal.

Referring to FIGS. 17 and 18, a sixth preferred embodiment of the present invention will be illustrated. Also in this embodiment, two couples of CMOS transistors 41-1, 51-1 and 41-2′, 51-2′ are connected in parallel to an electrode pad 37 b for each pixel at their source electrodes. The electrode pad 37 b, however, is separated into two portions 37 b-1 and 37 b-2 each independently connected to a corresponding one of the two CMOS transistors in the same manner as FIG. 10(B). These CMOS transistors are manufactured in the steps explained above in conjunction with the first embodiment except for the number of the transistors. The similar elements are given similar numerals as in the first embodiment. Then, each pixel comprises two individual sub-pixels. In accordance with this embodiment, even if the operation of one of the sub-pixels is fault, the other sub-pixel can support the operation of the pixel and therefore the possibility of deterioration in grey scale is substantially decreased. Also, even when the operational speed of one sub-pixel becomes low, the quality of the displayed image is not so deteriorated.

The representative example of the driving method in accordance with the sixth embodiment of the present invention will be explained with reference to FIG. 18. In FIG. 18, explanation is made for the display as shown in FIG. 17 but expanded in a 4×4 matrix. The configuration, however, is substantially identical except the number of pixels. FIG. 18 illustrates the control signals applied to the V_(D D) lines, the V_(S S) lines, the V_(G G) lines and the back electrode in the same manner as the fourth embodiment. In this driving method, the control signals applied to the V_(D D) and Vss lines are addressing signals which scan from the first row to the forth row as shown in FIG. 18. Opposed pulses are applied to the V_(D D) and Vss lines connected to an addressed row. The control signals applied to the V_(G G) lines are data signals which determine the visual pattern appearing on the display. In this embodiment, however, control signals applied to the V_(G G) lines are positive or negative pulses whose pulse width is only one 16th of one frame (e.g. between T₁ and T₂). The pulse width of addressing signals applied to the V_(D D) and Vss lines is on the other hand one fourth of the frame in the same manner as the second embodiment. The 16th division fashion is suitable for color displays.

If a pixel on the i-th row and the j-th column is desired to be actuated, a positive pulse is applied to the V_(G G) line of the j-th column at the time when the i-th row is addressed by applying opposed pulses to the VDD and Vss lines on the i-th row. In FIG. 18, the pixel on the first column and the first row is actuated in the first frame between T₁ and T₂. The back electrode is biased by a negative voltage between T₁ and T₃. The V_(D D), Vss and V_(G G) signal levels and the bias voltage are for example 20V, −20V, 120V and 110V respectively in the case that the optical characteristic of the liquid crystal is changed by the threshold voltage of 20V in the same manner. Accordingly, as understood from FIG. 18, such a high voltage as 30V is applied only to the selected pixel while the voltage level applied to the other pixel can not exceed 10V. In T₃ to T₄ in FIG. 18, the voltage levels at the V_(G G) lines and the back electrode are inversed so that the sign of the applied voltage on each pixel is simply inversed. Accordingly, such a low voltage as −30V is applied only to the selected pixel while the absolute voltage level applied to the other pixel can not exceed 10V. The pixel on the first column and the first row is actuated in the third frame between T₃ and T₄. The inversion of the signs takes place repeatedly once per several frames to several tens of frames so that the average voltage applied to the liquid crystal approaches to zero resulting in effective prevention of deterioration of the liquid crystal.

The foregoing description of preferred embodiments has been presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form described, and obviously many modifications and variations are possible in light of the above teaching. The embodiment was chosen in order to explain most clearly the principles of the invention and its practical application thereby to enable others in the art to utilize most effectively the invention in various embodiments and with various modifications as are suited to the particular use contemplated. Examples are as follows:

The above embodiments are applications in the form of CMOSs for switching devices in liquid crystal displays. The TFT in accordance with the present invention, however, can be utilized in the form of a switching device comprising one TFT for driving one pixel. In this case, the equivalent circuit is substantially same as that illustrated in FIG. 1 except that the resister R_(S D) is not effective because the N-type TFT is constructed with a spoiled semiconductor film which is not sensitive to incident light as explained above. The electrode pad of each pixel becomes electrically floating when not addressed in this modification so that the voltage level thereof may not be so fixed as compared with those utilizing CMOSs. The manufacturing process thereof, however, is very simple without the need of light blocking means.

The liquid crystal material used in the liquid crystal display may include other type materials. For example, a suitable phase transition liquid crystal materials can be prepared by adding an ion dopant into a nematic liquid crystal material of guest-host type or dielectric anisotropic type. The phase transition liquid crystal material changes, in accordance with application of an electric field, its optical appearance from a transparent state to a cloudy state and vice versa through phase transition between its nematic phase and its cholesteric phase. Furthermore in place of liquid crystals, suitable light influencing materials are also utilized in the same purpose such as electrophoresis dispersions which are prepared by dispersing pigment particles in an organic liquid which has been colored by a dye. If grey scale is desired, a plurality of frames are given to one image to be displayed and selected pixels are actuated only in a fewer frames than the given frames in accordance with the desired grey tone.

The present invention can be applied to displays utilizing other types of semiconductor devices such as germanium or silicon/germanium (Si_(x)Ge, .) semiconductor devices, in which case the thermal treatment can be done at temperatures approx. 100° C. lower than those used for silicon semiconductors in the above embodiments. The deposition of such semiconductor can be carried out by sputtering in a high energy hydrogen plasma caused by optical energy (shorter than 1000 nm wavelength) or electron cyclotron resonance (ECR). Instead of gases including hydrogen molecules, some hydrogen compounds can be used as the atmosphere of sputtering as long as not to be impurity. For example, monosilane or disilane may be used for forming silicon semiconductor transistors. Although in the preferred embodiments, oxide and semiconductor films are deposited respectively in separate apparatuses, it is apparently also possible to deposit other types of gate insulating films or gate electrodes in a common apparatus. During deposition of oxide films, a halogen such as fluorine may be used as an atmosphere of sputtering so as to introduce halogen atoms into the oxide films in order to effectively prevent alkali metal atoms from getting into the film from the glass substrate by virtue of neutralization. The same effect can be expected by introduction of phosphorus in place of halogens.

The present invention can be applied for other types of optical devices utilizing semiconductor devices such as image sensors, load elements or three-dimensional elements of monolithic integrated semiconductor devices. In the preferred embodiments field effect transistors are formed on a glass substrate. However, other substrates can be used instead. For example, thin film field effect transistors may be formed on a silicon substrate in a liquid crystal display or an image sensor device. This silicon substrate may be an intrinsic silicon substrate, a p-type silicon substrate, an n-type silicon substrate, or a silicon substrate in which MOSFETs, bipolar transistors, or the like are provided in the form of IC. An insulating layer is provided between such a substrate and the thin film field effect transistors although such an insulating layer may be dispensed with in the case of the intrinsic silicon substrate.

A gate electrode may be either a single layer electrode or a multi-layer electrode in a gate insulated field effect transistor in accordance with the present invention. The single layer gate electrode may be a silicon electrode doped with phosphorus or an aluminum electrode. The multi-layer gate electrode may be a two-layer electrode which consists of a lower chromium layer and an upper aluminum layer formed thereon or a two-layer electrode which consists of a lower silicon layer doped with phosphorus and an upper metallic or metal silicide layer formed thereon. The aluminum single layer electrode and the upper aluminum layer can be formed by sputtering an aluminum target. The silicon single layer electrode and the lower silicon layer can be formed by low pressure CVD or by sputtering a silicon target doped with phosphorus. The lower chromium layer can be formed by sputtering a chromium target. The metallic layer may be a molybdenum layer formed by sputtering a molybdenum target, a wolfram layer formed by sputtering a wolfram target, a titanium layer formed by sputtering a titanium target, or an aluminum layer formed by sputtering an aluminum target. The metal silicide layer may be a MoSi₂ layer formed by sputtering a MoSi₂ target, a WSi₂ layer formed by sputtering a WSi₂ target, or a TiSi₂ layer formed by sputtering a TiSi₂ target. Although the production method claims as provided infra include several steps, the order of these steps can be changed in accordance with the practical cases and should not limit the scope of patent. 

1. An active matrix display device comprising: a substrate; a first signal line formed over the substrate; a second signal line formed over the substrate and extending across the first signal line; a thin film transistor formed over the substrate, the thin film transistor including a gate electrode electrically connected to the first signal line, a source region, a drain region and a channel region wherein one of the source region and the drain region is electrically connected to the second signal line; an organic resin film formed over the first signal line, the second signal line and the thin film transistor; and a pixel electrode formed over the organic resin film, the pixel electrode being electrically connected to the other one of the source region and the drain region; wherein the pixel electrode extends over the first signal line so that a first portion of the pixel electrode is located on a first side of the first signal line while a second portion of the pixel electrode is located on a second side of the first signal line.
 2. The active matrix display device according to claim 1, wherein the organic resin film comprises polyimide.
 3. The active matrix display device according to claim 1, further comprising a second thin film transistor electrically connected to the pixel electrode.
 4. The active matrix display device according to claim 1, wherein the thin film transistor has a top-gate structure.
 5. An active matrix display device comprising: a first substrate; a first signal line formed over the first substrate; a second signal line formed over the first substrate and extending across the first signal line; a thin film transistor formed over the first substrate, the thin film transistor including a gate electrode electrically connected to the first signal line, a source region, a drain region and a channel region wherein one of the source region and the drain region is electrically connected to the second signal line; an organic resin film formed over the first signal line, the second signal line and the thin film transistor; a pixel electrode formed over the organic resin film, the pixel electrode being electrically connected to the other one of the source region and the drain region; a second substrate opposed to the first substrate; and a liquid crystal material interposed between the first substrate and the second substrate, wherein the pixel electrode extends over the first signal line so that a first portion of the pixel electrode is located on a first side of the first signal line while a second portion of the pixel electrode is located on a second side of the first signal line.
 6. The active matrix display device according to claim 5, wherein the organic resin film comprises polyimide.
 7. The active matrix display device according to claim 5, further comprising a second thin film transistor electrically connected to the pixel electrode.
 8. The active matrix display device according to claim 5, wherein the thin film transistor has a top-gate structure.
 9. An active matrix display device comprising: a substrate; a first signal line formed over the substrate; a second signal line formed over the substrate and extending across the first signal line; a thin film transistor formed over the substrate, the thin film transistor including a gate electrode electrically connected to the first signal line, a source region, a drain region and a channel region wherein one of the source region and the drain region is electrically connected to the second signal line; a planarizing insulating film formed over the first signal line, the second signal line and the thin film transistor; and a pixel electrode formed over the planarizing insulating film, the pixel electrode being electrically connected to the other one of the source region and the drain region; wherein the pixel electrode extends over the first signal line so that a first portion of the pixel electrode is located on a first side of the first signal line while a second portion of the pixel electrode is located on a second side of the first signal line.
 10. The active matrix display device according to claim 9, wherein the planarizing insulating film is an organic resin film.
 11. The active matrix display device according to claim 9, further comprising a second thin film transistor electrically connected to the pixel electrode.
 12. The active matrix display device according to claim 9, wherein the thin film transistor has a top-gate structure.
 13. An active matrix display device comprising: a first substrate; a first signal line formed over the first substrate; a second signal line formed over the first substrate and extending across the first signal line; a thin film transistor formed over the first substrate, the thin film transistor including a gate electrode electrically connected to the first signal line, a source region, a drain region and a channel region wherein one of the source region and the drain region is electrically connected to the second signal line; a planarizing insulating film formed over the first signal line, the second signal line and the thin film transistor; a pixel electrode formed over the planarizing insulating film, the pixel electrode being electrically connected to the other one of the source region and the drain region; a second substrate opposed to the first substrate; and a liquid crystal material interposed between the first substrate and the second substrate, wherein the pixel electrode extends over the first signal line so that a first portion of the pixel electrode is located on a first side of the first signal line while a second portion of the pixel electrode is located on a second side of the first signal line.
 14. The active matrix display device according to claim 13, wherein the planarizing insulating film is an organic resin film.
 15. The active matrix display device according to claim 13, further comprising a second thin film transistor electrically connected to the pixel electrode.
 16. The active matrix display device according to claim 13, wherein the thin film transistor has a top-gate structure.
 17. An active matrix display device comprising: a substrate; a first signal line formed over the substrate; a second signal line formed over the substrate and extending across the first signal line; a thin film transistor formed over the substrate, the thin film transistor including a gate electrode electrically connected to the first signal line, a source region, a drain region and a channel region wherein one of the source region and the drain region is electrically connected to the second signal line; an organic resin film formed over the first signal line, the second signal line and the thin film transistor; and a transparent pixel electrode formed over the organic resin film, the transparent pixel electrode being electrically connected to the other one of the source region and the drain region; wherein the transparent pixel electrode extends over the first signal line from a first side of the first signal line to a second side of the first signal line.
 18. The active matrix display device according to claim 17, wherein the organic resin film comprises polyimide.
 19. The active matrix display device according to claim 17, further comprising a second thin film transistor electrically connected to the transparent pixel electrode.
 20. The active matrix display device according to claim 17, wherein the thin film transistor has a top-gate structure.
 21. An active matrix display device comprising: a first substrate; a first signal line formed over the first substrate; a second signal line formed over the first substrate and extending across the first signal line; a thin film transistor formed over the first substrate, the thin film transistor including a gate electrode electrically connected to the first signal line, a source region, a drain region and a channel region wherein one of the source region and the drain region is electrically connected to the second signal line; an organic resin film formed over the first signal line, the second signal line and the thin film transistor; a transparent pixel electrode formed over the organic resin film, the transparent pixel electrode being electrically connected to the other one of the source region and the drain region; a second substrate opposed to the first substrate; and a liquid crystal material interposed between the first substrate and the second substrate, wherein the transparent pixel electrode extends over the first signal line from a first side of the first signal line to a second side of the first signal line.
 22. The active matrix display device according to claim 21, wherein the organic resin film comprises polyimide.
 23. The active matrix display device according to claim 21, further comprising a second thin film transistor electrically connected to the transparent pixel electrode.
 24. The active matrix display device according to claim 21, wherein the thin film transistor has a top-gate structure.
 25. An active matrix display device comprising: a substrate; a first signal line formed over the substrate; a second signal line formed over the substrate and extending across the first signal line; a thin film transistor formed over the substrate, the thin film transistor including a gate electrode electrically connected to the first signal line, a source region, a drain region and a channel region wherein one of the source region and the drain region is electrically connected to the second signal line; a planarizing insulating film formed over the first signal line, the second signal line and the thin film transistor; and a transparent pixel electrode formed over the planarizing insulating film, the transparent pixel electrode being electrically connected to the other one of the source region and the drain region; wherein the transparent pixel electrode extends over the first signal line from a first side of the first signal line to a second side of the first signal line.
 26. The active matrix display device according to claim 25, wherein the planarizing insulating film is an organic resin film.
 27. The active matrix display device according to claim 25, further comprising a second thin film transistor electrically connected to the transparent pixel electrode.
 28. The active matrix display device according to claim 25, wherein the thin film transistor has a top-gate structure.
 29. An active matrix display device comprising: a first substrate; a first signal line formed over the first substrate; a second signal line formed over the first substrate and extending across the first signal line; a thin film transistor formed over the first substrate, the thin film transistor including a gate electrode electrically connected to the first signal line, a source region, a drain region and a channel region wherein one of the source region and the drain region is electrically connected to the second signal line; a planarizing insulating film formed over the first signal line, the second signal line and the thin film transistor; a transparent pixel electrode formed over the planarizing insulating film, the transparent pixel electrode being electrically connected to the other one of the source region and the drain region; a second substrate opposed to the first substrate; and a liquid crystal material interposed between the first substrate and the second substrate, wherein the transparent pixel electrode extends over the first signal line from a first side of the first signal line to a second side of the first signal line.
 30. The active matrix display device according to claim 29, wherein the planarizing insulating film is an organic resin film.
 31. The active matrix display device according to claim 29, further comprising a second thin film transistor electrically connected to the transparent pixel electrode.
 32. The active matrix display device according to claim 29, wherein the thin film transistor has a top-gate structure. 